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An oil film bearing assembly rotatably supports the neck of a roll in a
rolling mill. The bearing assembly comprises a housing containing a
sleeve bearing and a thrust bearing. A circular lock assembly coacts with
the thrust bearing to axially retain the bearing assembly on the roll
neck. The lock assembly is axially received on and is rotatable into and
out of mechanical interengagement with the roll neck. First bearing
elements are carried by and project inwardly from the lock assembly to
contact a surface of the roll neck at a first location, and second
bearing elements project inwardly from the housing to contact an outer
surface of the lock assembly at a second location spaced axially from the
first location.

1. An oil film bearing for rotatably supporting the neck of a roll in a rolling mill, said bearing comprising: a housing containing a sleeve bearing and a thrust bearing; a circular
lock assembly coacting with said thrust bearing to axially retain said bearing on said roll neck, said lock assembly being axially received on and rotatable into and out of mechanical interengagement with said roll neck; first bearing elements carried
by and projecting inwardly from said lock assembly to contact a surface of said roll neck at a first location; and second bearing elements projecting inwardly from said housing to contact an outer surface of said lock assembly at a second location
spaced axially from said first location.

2. The oil film bearing of claim 1 wherein said first bearing elements comprise ball-type bearings.

3. The oil film bearing of claim 1 wherein said second bearing elements comprise roller-type bearings.

4. The oil film bearing of claim 3 wherein said second bearing elements are urged radially inwardly by resilient force exerting means.

5. The oil film bearing of claim 4 wherein said second bearing elements are carried on an arcuate platform acted upon by said resilient force exerting means.

6. The oil film bearing of claim 1 wherein said second bearing elements are urged radially inwardly by hydraulically actuated means.

7. The oil film bearing of claim 6 wherein said second bearing elements are carried on an arcuate platform acted upon by said hydraulically actuated means.

8. The oil film bearing of claim 1 wherein said lock assembly is mechanically interengaged with said roll neck by means of a bayonet-type connection.

9. The oil film bearing of claim 1 wherein said circular lock assembly comprises a piston adapted to be mechanically interengaged with said roll neck, and a cylinder surrounding said piston, said first bearing elements being carried by and
projecting inwardly from said piston, and said second bearing elements being carried by and projecting inwardly from a component of said housing.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates generally to oil film bearings that are used to rotatably support the necks of rolls in a rolling mill.

2. Description of the Prior Art

Rolling mill oil film bearings are typically held in place by lock assemblies that are rotated into and out of mechanical interengagement with the roll necks. In the larger size bearings, e.g., those with rolls measuring one and one half meters
in diameter and larger, lock rotation requires relatively large clearances between the coacting roll neck and lock assembly surfaces, which in turn gives rise to a tendency of the lock assemblies to tilt, misalign, and bind during mounting and
dismounting. This problem is further exacerbated by the weight of the larger lock assemblies, which can exceed 900 kilograms.

The objective of the present invention is to ease the task of rotating the lock assemblies into and out of mechanical interengagement with the roll necks by incorporating strategically placed bearings that encourage proper alignment while
avoiding the tendency of the lock assemblies to tilt and bind.

SUMMARY OF THE INVENTION

In accordance with the present invention, an oil film bearing comprises a chock and associated end plates forming a housing that contains both sleeve bearing and thrust bearing components. A circular lock assembly coacts with the thrust bearing
component to axially retain the oil film bearing on the roll neck. The lock assembly is rotatable into and out of mechanical interengagement with the roll neck. First bearing elements are carried by and project inwardly from the lock assembly to
contact a surface of the roll neck at a first location. Second bearing elements project inwardly from a chock end plate of the housing to contact an outer surface of the lock assembly at a second location spaced axially from the first location. The
first and second bearing elements encourage proper alignment of the lock assembly on the roll neck, thus avoiding or at least significantly minimizing the tendency of the lock assembly to tilt and bind during mounting and dismounting.

BRIEF
DESCRIPTION OF THE DRAWINGS

FIG. 1 is a longitudinal sectional view taken through an oil film bearing embodying the concepts of the present invention;

FIG. 2 is an enlarged view of the circled portion of FIG. 1;

FIG. 3 is a sectional view taken along line 3-3 of FIG. 2;

FIG. 4 is a horizontal plan view of the components shown in FIG. 3;

FIGS. 5 and 7, and 6 and 8 are respectively views similar to FIGS. 3 and 4, depicting alternative embodiments of the invention; and

FIGS. 9A and 9B are schematic illustrations depicting successive stages in achieving interlocked engagement of the lock assembly with the roll neck.

DETAILED DESCRIPTION OF ILLUSTRATED EMBODIMENTS

With reference initially to FIG. 1, a rolling mill roll 10 has a tapered section 12 leading to an end having reduced diameter cylindrical intermediate sections 14, 16, the latter being separated from a cylindrical end section 18 by cylindrical
section 20 and circular groove 22. An oil film bearing 24 includes a chock 26 cooperating with end plates 28 and 30 and a cover 32 to define a housing containing a thrust bearing 34 and a sleeve bearing comprised of a sleeve 36 rotatably fixed to the
tapered neck section 12 by keys 38, with the sleeve in turn being rotatably journalled in a bushing 40 fixed within the chock 26.

A thrust ring 42 is interposed between the sleeve 36 and thrust bearing 34, and a lock assembly 44 coacts with the inner race 34a of the thrust bearing 34 to axially retain the oil film bearing on the roll neck.

As can best be seen by further reference to FIG. 2, the lock assembly 44 includes a piston 46 surrounded by a cylinder 48 comprised of mating ring-shaped components 48a, 48b interconnected by fasteners 50. The cylinder 48 defines an interior
space subdivided by a piston ring 52 into chambers 54a, 54b.

The piston 46 is interengaged with the roll neck by means of a bayonet-type connection. More particularly, with reference to FIG. 9A, the piston 46 has inwardly projecting splines 46a angularly separated by grooves 46b, and the roll end section
18 has complimentary outwardly projecting splines 18a angularly separated by grooves 18b. In FIG. 9A, the piston splines 46a are aligned axially with the neck grooves 18b and the piston grooves 46b are aligned with the neck splines 18a, thus allowing
the lock assembly to be axially mounted on an removed from the roll neck. A shown in FIG. 9B, a 45.degree. rotation of the lock assembly will result in the piston splines 46a being aligned with the roll neck splines 18a, thus establishing an
interlocked interengagement which axially fixes the lock assembly 44 relative to the roll neck.

Once the lock assembly is fixed axially on the roll neck, hydraulic fluid can be introduced into cylinder chamber 54a to urge the cylinder 48 to the left as viewed in FIGS. 1 and 2, thus urging the thrust bearing 34 in the same direction to seat
the oil film bearing on the roll neck. Thereafter, a lock nut 58 threaded as at 60 on piston 46 is tightened to axially retain the cylinder in place, allowing the hydraulic pressure in chamber 54a to be relieved.

Removal of the oil film bearing is accomplished by first loosening the lock nut 58 and then hydraulically pressurizing chamber 54b, causing the cylinder 48 to move to the right as viewed in FIGS. 1 and 2. An external shoulder 62 on the cylinder
then coacts with an interior ring 64 of outer end plate 30 (see FIG. 1) to axially dislodge the oil film bearing from the roll neck.

As previously noted, during mounting and dismounting of the oil film bearing, the lock assembly 44 has a tendency to tilt and bind. To resist this tendency, first ball-type bearing elements 66 are carried by and project inwardly from the piston
46 to contact the reduced diameter section 16 of the roll neck at a first location. Second roller-type bearing elements 68 project inwardly from the outer end plate 30 to contact the outer surface of the cylinder component 48b at a second location
spaced axially from the first location contacted by the first bearing elements. The first and second bearing elements 66, 68 coact to resist tilting of the lock assembly, thus avoiding binding as it rotates into and out of interlocked engagement with
the roll neck.

As shown in FIGS. 3 and 4, the roller-type bearing elements 68 may be carried on an arcuate platform 70 urged radially inwardly by resilient force exerting means in the form of springs 72. Alternatively, as shown in FIGS. 5 and 6, the arcuate
platform can be urged radially inwardly by hydraulically actuated means in the form of a piston 74.

In still another embodiment, as shown in FIGS. 7 and 8, the roller-type bearing elements 68 can simply be located in pockets 76 and rotatably supported on pins 78 fixed with respect to the chock end plate 30.